生物炭
吸附
化学
水溶液
朗缪尔吸附模型
吸热过程
核化学
铀
氢氧化物
吸附剂
无机化学
热解
磷酸盐
有机化学
材料科学
冶金
作者
Peng Lyu,Guanghui Wang,Bing Wang,Yin QiuLing,Yingjie Li,Nansheng Deng
标识
DOI:10.1016/j.clay.2021.106146
摘要
Abstract The phosphate pre-impregnation pyrolysis followed by a hydrothermal method was used to synthesize a novel phosphate-impregnation biochar (PBC) cross-linked Mg Al layered double-hydroxide composite (PBC@LDH) for U(VI) removal from aqueous solution. Physicochemical analysis revealed that the PBC@LDH possessed the high surface area and abundant surface functional groups. XPS and FTIR analysis confirmed that the highly efficient adsorption of U(VI) by PBC@LDH was attributed to the strong complexation and reduction reaction of P O, Mg–O–H, and –OH groups to U(VI) as well as the co-precipitation of polyhydroxy aluminum cations captured U(VI). Adsorption equilibrium of U(VI) on PBC@LDH was reached within 2 h of contact time, and the process of the material for U(VI) adsorption was optimally described with the pseudo-second-order kinetic model (R2nd2>0.99). Moreover, the adsorption isotherm of U(VI) on PBC@LDH was better simulated by the Langmuir model (RLan2>0.97). The maximum adsorption capacity of U(VI) by the PBC@LDH was calculated to be ⁓274.15 mg/g at pHinitial 4 and 298 K, which was an improvement of ⁓17 times than that of unmodified biochar and, furthermore, PBC@LDH texted had the most strongly adsorb U(VI) between approximately pHinitial 4 and 8. It was verified an endothermic, favorable, and spontaneous adsorption process. After five successive sorbent reuses, the elimination rate was still 77.9%. These results suggest that PBC@LDH is a promising candidate for desirable separation of uranium from uranium-waste water.
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